Your search keyword '"Zhao, Runmao"' showing total 5 results

1. A review of global precision land-leveling technologies and implements: Current status, challenges and future trends

Author

Chen, Gaolong, Hu, Lian, Luo, Xiwen, Wang, Pei, He, Jie, Huang, Peikui, Zhao, Runmao, Feng, Dawen, and Tu, Tuanpeng

Published

2024

2. An improved YOLOv7 network using RGB-D multi-modal feature fusion for tea shoots detection

Author

Wu, Yanxu, Chen, Jianneng, Wu, Shunkai, Li, Hui, He, Leiying, Zhao, Runmao, and Wu, Chuanyu

Published

2024

3. Visual navigation in orchard based on multiple images at different shooting angles.

Author

MA Zenghong, YUE Jiawen, YIN Cheng, ZHAO Runmao, Mulongoti, CHANDA, and DU Xiaoqiang

Subjects

RADIO interference, NAVIGATION, ORCHARDS, CAMELLIA oleifera, KALMAN filtering, GLOBAL Positioning System

Abstract

Copyright of Journal of Intelligent Agriculture Mechanization is the property of Nanjing Institute of Agricultural Mechanization and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

4. Design and Experiment of Ordinary Tea Profiling Harvesting Device Based on Light Detection and Ranging Perception.

Author

Huan, Xiaolong, Wu, Min, Bian, Xianbing, Jia, Jiangming, Kang, Chenchen, Wu, Chuanyu, Zhao, Runmao, and Chen, Jianneng

Subjects

OPTICAL radar, LIDAR, PLANT surfaces, RAPID prototyping, HARVESTING machinery

Abstract

Due to the complex shape of the tea tree canopy and the large undulation of a tea garden terrain, the quality of fresh tea leaves harvested by existing tea harvesting machines is poor. This study proposed a tea canopy surface profiling method based on 2D LiDAR perception and investigated the extraction and fitting methods of canopy point clouds. Meanwhile, a tea profiling harvester prototype was developed and field tests were conducted. The tea profiling harvesting device adopted a scheme of sectional arrangement of multiple groups of profiling tea harvesting units, and each unit sensed the height information of its own bottom canopy area through 2D LiDAR. A cross-platform communication network was established, enabling point cloud fitting of tea plant surfaces and accurate estimation of cutter profiling height through the RANSAC algorithm. Additionally, a sensing control system with multiple execution units was developed using rapid control prototype technology. The results of field tests showed that the bud leaf integrity rate was 84.64%, the impurity rate was 5.94%, the missing collection rate was 0.30%, and the missing harvesting rate was 0.68%. Furthermore, 89.57% of the harvested tea could be processed into commercial tea, with 88.34% consisting of young tea shoots with one bud and three leaves or fewer. All of these results demonstrated that the proposed device effectively meets the technical standards for machine-harvested tea and the requirements of standard tea processing techniques. Moreover, compared to other commercial tea harvesters, the proposed tea profiling harvesting device demonstrated improved performance in harvesting fresh tea leaves. [ABSTRACT FROM AUTHOR]

Published

2024

5. TCNet: Transformer Convolution Network for Cutting-Edge Detection of Unharvested Rice Regions.

Author

Yang, Yukun, He, Jie, Wang, Pei, Luo, Xiwen, Zhao, Runmao, Huang, Peikui, Gao, Ruitao, Liu, Zhaodi, Luo, Yaling, and Hu, Lian

Subjects

TRANSFORMER models, FEATURE extraction, CONVOLUTIONAL neural networks, RICE processing, RICE

Abstract

Cutting-edge detection is a critical step in mechanized rice harvesting. Through visual cutting-edge detection, an algorithm can sense in real-time whether the rice harvesting process is along the cutting-edge, reducing loss and improving the efficiency of mechanized harvest. Although convolutional neural network-based models, which have strong local feature acquisition ability, have been widely used in rice production, these models involve large receptive fields only in the deep network. Besides, a self-attention-based Transformer can effectively provide global features to complement the disadvantages of CNNs. Hence, to quickly and accurately complete the task of cutting-edge detection in a complex rice harvesting environment, this article develops a Transformer Convolution Network (TCNet). This cutting-edge detection algorithm combines the Transformer with a CNN. Specifically, the Transformer realizes a patch embedding through a 3 × 3 convolution, and the output is employed as the input of the Transformer module. Additionally, the multi-head attention in the Transformer module undergoes dimensionality reduction to reduce overall network computation. In the Feed-forward network, a 7 × 7 convolution operation is used to realize the position-coding of different patches. Moreover, CNN uses depth-separable convolutions to extract local features from the images. The global features extracted by the Transformer and the local features extracted by the CNN are integrated into the fusion module. The test results demonstrated that TCNet could segment 97.88% of the Intersection over Union and 98.95% of the Accuracy in the unharvested region, and the number of parameters is only 10.796M. Cutting-edge detection is better than common lightweight backbone networks, achieving the detection effect of deep convolutional networks (ResNet-50) with fewer parameters. The proposed TCNet shows the advantages of a Transformer combined with a CNN and provides real-time and reliable reference information for the subsequent operation of rice harvesting. [ABSTRACT FROM AUTHOR]

Published

2024